Intralytix is using its core
bacteriophage technology to develop safe and effective products
based on naturally-occurring bacteriophages, for use in food
production and processing, environmental cleanliness, veterinary
applications, and human therapy.

Bacteriophages: the Most Ubiquitous Organisms on Earth

Bacteriophages (or phages for short) are viruses that infect
bacteria. The name was coined by one of the discoverers of
bacteriophages (Felix d'Herelle), by combining the Greek "phago"
meaning "to eat" or "to develop at the expense of," and
"bacteria." Phages are the most ubiquitous organisms on Earth,
and they can be found – often in prodigious numbers – in every
living ecosystem. Phages are highly specific for bacteria, and
they can not infect eukaryotic cells; i.e., those of
humans/animals and plants. Moreover, one phage typically only infects a
subgroup of strains within the same bacterial species, therefore not disturbing
any beneficial or "good" microbes.

Philosophical and Technical Considerations

Intralytix's phage technology is based on the philosophy that
naturally-occurring bacteriophages provide one of the safest and
most environmentally-friendly, targeted approaches for dealing
with bacterial infections in a variety of settings. Phages are
"Nature's way" of controlling bacteria on this planet, and they
have played and continue to play a critical role in maintaining
(via a well-balanced predator-prey relationship) microbial
balance in every ecosystem where bacteria are present. Thus,
Intralytix's philosophy is to use this natural approach to
control pathogenic bacteria in limited, specific settings where
those bacteria may cause human illness or other problems.

Intralytix's core phage technology stipulates construction of
natural, safe, and effective phage preparations from a library
of well-characterized bacteriophages isolated from the
environment. After they are in Intralytix's phage collection,
the phages are not genetically engineered or altered in any way.
However, they are rigorously characterized and carefully
selected to produce phage cocktails optimal for specific
applications. At the present time, Intralytix's library of lytic
bacteriophages is one of the largest and best characterized in
the world. Also, it is continuously being updated with new
phages, in order to include bacteriophages lytic against
additional bacterial pathogens or bacterial strains of
particular concern in specific geographic locations or in
specific food processing or clinical settings.

Phages vs. Bacteria: Mechanisms of Action

Phages are metabolically inert in their extracellular state
and they reproduce by hijacking the metabolism
of their host bacteria. After phage DNA is injected into the
host cell, it directs the production of progeny phages. These
phages burst from the host cell, killing it, and then infect
more bacteria. There are innumerable types of phages, each
capable of eradicating a specific bacterial host species. Phages
are abundant in the biosphere and they are "Nature's way" of
controlling bacteria in virtually every ecosystem where bacteria
are present. Phages only attack bacteria and have absolutely no
effect on human, animal, insect, plant, etc. cells. Even across
bacteria types, a phage does not nonspecifically infect and lyse all
bacterial species; rather, it kills strains or a subgroup of
strains within the targeted bacterial species, which makes
targeted therapy possible. Because of this specificity, phages
may be considered the most gentle, natural, and effective way to
target "problem bacteria" in specific settings, without
affecting other bacteria (which often are beneficial) and
without adversely affecting the environment.

The mechanism by which phages kill their
specific host bacteria is commonly called "lysis." There are
four major steps in the phage-mediated lytic process:

Recognition and binding

The distal tips of a phage's tail
fibers bind specifically to receptors in the host
bacterium's cytoplasmic membrane

Injection

Phage DNA is injected from the
phage into the host cell's cytoplasm

Multiplication

Phage DNA replication is initiated,
phage-specific proteins are synthesized, and new phages
are assembled. During these steps, the host cell's DNA
transcription is suppressed and its metabolic resources
are directed towards phage replication, assembly, etc.

Lysis

Very shortly after infection, the infected
cell dies metabolically (i.e., it stops producing ATP). This
leads to membrane-disruption later in the phage's lytic cycle,
which enables large numbers of newly assembled phage particles
to be released from the bacterium and the host cell's death.
Although the entire process requires approximately 20-40 minutes
(it varies from phage to phage), most lytic phage-infected cells
are metabolically dead by only 20-40 seconds post-injection of
phage DNA.

See the
animated simulation (below) of the above-described
process.

Areas of Practical Applications

Properly developed and manufactured phage preparations can be
invaluable in controlling problem bacteria in various settings
where the bacteria may cause disease or other problems. Thus,
phage preparations can potentially be useful in any setting
where the eradication of problem bacteria is important. While
such areas of applications are numerous, Intralytix has
identified four major areas for product development and
commercialization of its phage-based technology. They are
applications for: